Even though today's largest airplane engines are capable of producing more than 100,000 pounds of thrust, they are still susceptible to ice build-up in the sub-zero temperatures at cruising altitude. To ensure the next generation of mega-engines can withstand the worst that Old Man Winter can throw at them, GE has set up a testing center in the coldest, most inhospitable frozen environment this side of Hoth—Winnipeg, Canada.
In 2006, GE opened a brand-new state of-the-art cold-weather test cell at Mirabel International Airport in Montreal. But in just four years, the technology had outgrown the facilities capabilities—such is the march of aerospace advancement—and was told to pack up and move by airport authorities. Since building another test facility in Quebec—specifically laying a large enough concrete pad—would be prohibitively expensive, GE instead forged an alliance with StandardAero and together they built the $50 million Testing, Research and Development Center (TRDC) at Winnipeg's James A. Richardson International Airport.
To meet stringent FAA guidelines, aero engines are put through a grueling set of trials in sub-zero temperatures (4- and -20-deg C) to gauge their performance and endurance as well as rate the ability to handle bird strikes and icing. For temperatures that low, Winnipeg was the obvious choice. It's so cold there that Kevin Kanter, engineering executive of GE Aviation's Design & Integration Systems Engineering, estimated that the "icing window" (the part of the year when it sufficiently frosty to perform the tests) is "at least a month" wider than Quebec's, which runs from November to March.
The test cell itself is seated upon a 45-foot by 50-foot by 6-foot concrete foundation anchored into the ground by 45-foot wide, 30-foot deep caissons. This reinforcement is necessary to support not only the five (potentially six) mega engines that GE is currently developing—including three iterations of the CFM Leap, the Passport 20, the NG34, and the GE-9X—but also a massive array of seven 250HP variable frequency fan motors and their 16-foot diameter augmentor tube and 51-foot tallexhaust stack. These fans produce 150,000 pounds of thrust, move air at 2,800 lb/s, and consume 2MW of power at peak output. They're also really noisy. To minimize the disturbance to the nearby airport, the test cell is surrounded by 50-foot tall noise dampening walls. The wall of cold air mixes with 125 separate jets of hot water to generate the simulated ice cloud.
The cost of operating such a massive test cell: a cool million every month.